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Article

Removal of Arsenate from Contaminated Water via Combined Addition of Magnesium-Based and Calcium-Based Adsorbents

Geological Survey of Japan, National Institute of Advanced Industrial Science and Technology (AIST), Central 7, 1-1-1 Higashi, Tsukuba 305-8567, Japan
*
Author to whom correspondence should be addressed.
Deceased author 16 July 2022.
Submission received: 1 February 2023 / Revised: 2 March 2023 / Accepted: 3 March 2023 / Published: 6 March 2023
(This article belongs to the Special Issue Wastewater Treatment and Purification)

Abstract

:
The effects of the combined addition of Mg- and Ca-based adsorbents (MgO, Mg(OH)2, MgCO3, CaO, Ca(OH)2, and CaCO3) were systematically tested for improving arsenic-removal performance and inhibiting the leaching of base material components from the adsorbent. Arsenic-removal tests were conducted with each single type or combination of two types of adsorbents. Results obtained after the combined-addition tests were compared with those obtained from the single-addition test with each adsorbent. The arsenic-removal performance improved in most combined additions but decreased in certain combined additions of MgO or Mg(OH)2 with Ca-based adsorbents. The arsenic-removal performance of the combined addition of MgCO3 and Ca(OH)2 was the highest. The combination of Mg-based adsorbents with CaO or Ca(OH)2 inhibited Mg-leaching, whereas that of CaO or Ca(OH)2 with MgCO3 inhibited Ca-leaching. Improvement in arsenic-removal performance for the combination of MgCO3 with CaO or Ca(OH)2 was caused by the incorporation and co-precipitation with arsenic when Mg(OH)2 and CaCO3 were produced. MgCO3-Ca(OH)2 and MgCO3-CaO are recommended for both arsenic removal and environmental adsorbent stability that can be effectively applied over a wide range of arsenic concentrations.

1. Introduction

Arsenic (As) is considerably toxic to humans and sourced not only from industrial and mine wastewater but also from natural groundwater. The World Health Organization (WHO) guidelines on drinking water quality introduced a provisional As guideline value of 0.01 mg/L and important points on its properties and health effects [1]. Consuming As-containing drinking water and food can cause chronic arsenicism, leading to dermal lesions, peripheral neuropathy, skin cancer, bladder and lung cancers, and peripheral vascular disease, as well as acute As intoxication [1]. As-contaminated groundwater is often directly consumed, especially in developing regions such as Southern and Southeast Asia [2,3,4,5,6,7,8,9,10,11,12,13,14,15,16], Western and Southern Africa [17,18], and Latin America [19,20,21,22,23].
Arsenic speciation and the effects of As on human health are detailed in Singh et al. [24]. The chemical speciation of inorganic arsenic species with strong toxicity among them is important for health effects. Common inorganic arsenic species include arsenate As(V) and arsenite As(III). Inorganic arsenic species are biomethylated in the human body and converted to monomethylarsonic acid (MMA) and dimethylarcinic acid (DMA), which are less toxic than inorganic arsenic. The order of toxicity of arsenicals is as follows: MMA(III) > As(III) > As(V) > MMA(V) = DMA(V). Monomethylarsonic acid (MA(III)) is a highly toxic intermediate product created during arsenic biotransformation. Prolonged intake of drinking water containing inorganic As causes various adverse health effects such as skin lesions, cardiovascular disease, neurological effects, chronic lung disease, cerebrovascular disease, reproductive disease, adverse renal affects, developmental abnormalities, hematological disorders, diabetes mellitus and cancers of skin, lung, liver, kidney and bladder.
The prevention of arsenic health hazards can only be achieved by properly treating As-contaminated water. There are many studies on As treatment methods such as membrane filtration, adsorption, coagulation, ion exchange, photocatalysis and photoelectrocatalysis. In developing countries, treatment methods involving inexpensive adsorbents are usually more likely to be used owing to economic and operational constraints. In the adsorption method, various adsorbents such as activated carbon, silica gel, iron-based adsorbents, and aluminum-based adsorbent are used. Some recent research on adsorbents for arsenic removal are presented below.
Fe-based adsorbents are popular materials that are often used for arsenic removal, and the arsenic adsorption mechanism has also been investigated. Liu et al. [25] investigated the adsorption mechanism of As(V) and As(III) on magnetite nanoparticles (MNPs). MNPs were synthesized using a modified Fe(II) and Fe(III) coprecipitation method under N2 protection. The specific surface area of MNPs was 39 m2/g. Although near-spherical primary particles with an average diameter of 34 nm, MNPs existed as larger aggregates under adsorption experimental condition. The aggregate size was 2.57 μm following a 30 min sonication, which increased to 5.1 μm after 24 h of shaking. As(V) and As(III) adsorption on MNPs reached equilibrium around 120 min. The adsorption equilibration time was set at 24 h to ensure complete reactions. Their experiments were performed at various initial As concentration, pH (5.0–9.0), ion strength (0–100 mM NaNO3) and temperature (10 to 40 or 50 °C). Their isotherm data were fitted with the linearized Langmuir equation and the maximum adsorption capacity slightly increased with increasing temperature. As(V) adsorption decreased monotonically with increasing pH. As(III) adsorption also started to decrease at pH greater than 7.0. As(V) and As(III) adsorptions were hardly affected by ionic strength. No major redox reaction occurred for the As(V) or As(III) adsorbed on MNPs under anoxic experimental conditions. Conversely, dramatic redox reactions occurred upon exposure to air during the overnight drying process. They described that the possible role of reactive Fe(II) atoms in the redox transformation of adsorbed As should not be ignored, because Fe atoms in magnetite are in Fe(II) and Fe(III) mixed-valence states [25]. A new type of Fe-based adsorbent processed into an easy-to-use shape has also been proposed. Lou et al. [26] reported the removal of As(V) using sponges loaded with Fe-based adsorbents. They were synthesized a composite material cube-shaped open-celled cellulose sponge loaded superparamagnetic iron oxide nanoparticles (SPION). To assess the As(V) adsorption performance of the adsorbents, batch adsorption experiments with various initial As(V) concentrations (0–800 mg/L), contact times (up to over 1400 min), and different temperatures (293 and 343 K) were performed. The solution pH was adjusted to 3.6 prior to the adsorption experiments to optimize the adsorption. The adsorption tests were performed by adding the sponge-loaded SPION (0.2 g) to As(V) solution (25 mL). From the results of the adsorption experiments, the following facts were mainly clarified: (1) The adsorption capacity increased when increasing the As(V) initial concentration. (2) The adsorption at 293 K was better than at 343 K. (3) The adsorption capacity became almost constant after 60 min. (4) The adsorption capacity was 69.68 mg/g for the initial As(V) concentration of 800 mg/L. In addition, they described that the best model for their adsorption isotherm data was Freundlich, which highlights the importance of the heterogeneous surface of the adsorbents. Moreover, from the XANES spectrum, they determined that As(V) was not reduced to As(III) after being adsorbed. Adsorption–desorption cycle experiments (initial As(V) concentration was 200 mg/L) were also performed. Then, they reported that the cube adsorbent maintained high adsorption capacity even after 5 adsorption–desorption cycles [26]. Noteworthy among more recent works on Fe-based adsorbents has been on the adsorbent composed of activated carbon (AC) and Fe3O4 [27]. They made AC by carbonizing powdered sugarcane bagasse mixed with H3PO4. Then, the AC and a solution including FeCl3·6H2O were mixed and hydrothermally treated using an autoclave to prepare a Fe3O4/AC composite adsorbent. Their As adsorption was more accurately described by the Langmuir isotherm, as compared to the Freundlich isotherm. They concluded that the number of active sites on the composite surface was limited, and a monolayer of As(III) was formed over the homogenous composite surface [27].
Another interesting study on As removal by novel adsorbents [28] prepared novel gelatin-PVA/La2O3 (GPL) composite by copolymerization of polyvinyl alcohol (PVA) and gelatin in the presence of La2O3 using glutaraldehyde as a cross-linker. The GPL composite proved to be a superior adsorbent because it could effectively remove both As(V) and As(III) from real wastewater samples and because it was reusable [28]. In addition, studies on manganese oxide adsorbents modified with transition elements have also been reported. Zhang et al. [29] investigated a cobalt (Co)-doped hausmannite (one of Mn oxide minerals) for the removal of As(III) and As(V) from water. The Co-doped hausmannite was synthesized from manganese sulfate (MnSO4·H2O), cobalt sulfate (CoSO4·7H2O), and sodium hydroxide (NaOH). Three Co-doped hausmannite samples with initial Co/Mn molar ratios of 0, 0.05 and 0.10 (HM, CoH5, and CoH10) were prepared using the co-precipitation method. The average particle size was 85, 131, and 103 nm for HM, CoH5, and CoH10. Correspondingly, the specific surface area was 12.4, 1.7 and 11.8 m2/g, respectively. As(V) adsorption experiments, As(V) adsorption isotherm experiments, and As(III) oxidation experiments were performed. For As(V) adsorption experiments, the initial As(V) concentration was 7.5 mg/L and adsorbent concentration of 1 g/L, ionic strength (0.01 mol/L, 0.1 mol/L, and 0.2 mol/L), and reaction pH (4.5, 5.5, 6.5 and 7.5) at 25 °C for 24 h. Adsorption isotherm experiments were conducted with initial As(V) concentrations of 0–60 mg/L. For As(III) oxidation experiments, the initial As(III) concentration was of 15.8 mg/L. The results of these experiments have revealed the following: ionic strength had no effect on the adsorption of As(V) onto the mineral surface. The As(V) adsorption density decreased, as pH increased from 4.5 to 7.5. The As(V) removal by Co-doped samples from the solution gradually decreased with increasing Co-doping level. The Freundlich model significantly better fit the data than did the Langmuir model, suggesting that the active sites on the Co-doped samples were energetically heterogeneous. As(III) was oxidated to As(V) by Mn(III) and then adsorbed on the mineral surface. During the As(III) oxidation by these Co-doped samples under the experimental conditions, large amounts of Mn(II) and Co(II) were released. EXAFS analysis revealed that only As(V) was adsorbed on the mineral surface [29].
In addition to the above studies on Fe-based adsorbents and so on, many studies on Mg-based and Ca-based adsorbents have been conducted for the purpose of As removal. Park et al. [30] used magnesium chloride or magnesium sulfate to remove As(V) from a molybdenum oxide processing plant liquid containing approximately 70 g/L of Mo(VI) and 470 mg/L of As(V). The addition of MgO as a precipitating agent was also tested. They reported that As(V) could be removed to less than 5 mg/L at pH 10.2, resulting in a pure Mo(VI) liquid by adding magnesium at a Mg:As molar ratio of at least 2:1. Addition of either MgCl2 and MgSO4 resulted in precipitation of Mg3(AsO4)2 and also Mg(OH)2 at pH 9–11. This formed Mg(OH)2 could also adsorb As(V). No such effect was observed with the addition of MgO. Park et al. also performed the As-removal tests using As(III) synthetic solution (450 mg/L as As). Adding 0.3 mol/L (24 g/L) of Mg, the pH range of 6–12 was tested. As(III) reached approximately 20 mg/L at pH 11. Removal of As(III) after oxidation by addition of H2O2 (a H2O2/As molar ratio of 3:1) was also tested. Within the range of pH 9–11, the residual As(V) after 20 min was less than 5 ppm for the Mg/As ratio of 3/1. [30]. Tresintsi et al. [31] suggested a procedure for the regeneration of iron oxyhydroxide arsenic adsorbents by granulated MgO. In their method, the arsenic desorbed from spent Fe-based adsorbents using NaOH aqueous solution was re-adsorbed on MgO. The optimum conditions of MgO application and the arsenic adsorption mechanism were examined through batch adsorption tests. A commercial fused MgO was used in the form of fine powder (<63 μm) for batch adsorption tests and granulated material (100–250 μm) for regeneration column tests. The surface morphological characteristics for the used MgO were a specific surface area of 59 m2/g, a pore volume 0.14 mL/g, and a mean pore diameter156 Å. The corresponding characteristics for the FeOOH were 155 m2/g, 0.23 mL/g, and 30 Å. In batch adsorption experiments, around 20–25 mg of fine powder of MgO were dispersed in 200 mL of As(III) or As(V) solutions inside flasks and the solutions were stirred at 20 °C for 24 h. Initial As(III) and As(V) concentrations varied between 0.25 and 12.5 mg/L. The tests were performed at pH values 10–12. The optimum pH for As(V) adsorption was 10, where a maximum adsorption capacity 59.4 mg-As(V)/g was calculated for residual concentration near 5 mg/L. In the case of As(III), the removal capacity is maximized at pH 11, where around 50 mg As(III)/g could be adsorbed for residual concentration 3 mg/L. As K-edge EXAFS spectra indicated a high probability of adsorption of As(V) and As(III) on Mg(OH)2 produced by hydrolysis of MgO [31]. Yu et al. [32] made a porous hierarchically micro/nanostructured MgO for As removal. Their MgO precursors were precipitates formed by mixing Mg(NO3)2 and K2CO3 solutions (at 293 K aging for 2 h). Two types of MgO precursors (flower-like and nest-like MgO precursors) were made by changing concentrations of K2CO3 (1 M and 0.5 M). The MgO precursors were calcined at 973 K for 4 h to produce two types of MgO. Using XRD identified the MgO precursors to be hydromagnesites. The two MgO precursors were assigned to flower-like hydromagnesite (F-hydromagnesite) and nest-like hydromagnesite (N-hydromagnesite), respectively. Correspondingly, the flower and nest-like MgO samples are assigned to F-MgO and N-MgO, respectively. The BET surface area of F- and N-hydromagnesite were approximately 21 and 18 m2/g. Those of F- and N-MgO were approximately 33 and 25 m2/g. For the comparisons of arsenic adsorption performance between MgO precursors and MgO, the initial As(III) and As(V) concentrations were approximately 4.6 and 7.2 mg/L, respectively. The adsorbent dose was 0.3 g/L in a comparison study. The adsorption capacity of two MgO was much higher than that of the hydromagnesites. The adsorption capacity of F-MgO and N-MgO for As(III) was approximately 252 mg/g and 644, respectively. That of F-MgO and N-MgO for As(V) was approximately 344 and 379 mg/g, respectively [32]. Opiso et al. [33] investigated the different mineral phases formed at alkaline condition in the Mg-Si-Al system and the sorption behavior of arsenate during and after mineral formation. In addition, the desorption of co-precipitated and adsorbed arsenate was conducted using phosphate-bearing solution. Their minerals were synthesized by mixing various volume ratios of Mg, Si, and Al solutions (Na2SiO3, Mg(NO3)2·6H2O and Al(NO3)3·9H2O) at room temperature and 50 °C, respectively. The sorption of arsenate was investigated during and after mineral formation at alkaline conditions (around pH11). For co-precipitation experiments, arsenate solution were added instantaneously during the mixing of Mg, Si, and Al solutions to be 100 mg/L of As(V) concentration. In the case of adsorption experiments, the same amounts of As(V) were added after mineral formation. The suspension was then shaken for 7 days. The results revealed that brucite (Mg(OH)2), hydrotalcite (Mg6Al2(CO3)(OH)16·4(H2O)), and serpentine (MgSi2O5(OH)4) have high uptake capacity for As(V) [33].
Camacho et al. [34] researched the effect of calcium addition as a stabilization agent on arsenic desorption from residues after ferric treatment of arsenic-contaminated water. They conducted laboratory and field tests using a calcium agent which was lime (CaO or Ca(OH)2). The calcium addition was found to reduce arsenate leaching from ferric residuals prepared in their laboratory. The treatment residual field sample was a granular ferric hydroxide material used for arsenic removal from groundwater. Lime as calcium hydroxide was used as a binder for solidification/stabilization of arsenic in the field sample and arsenic stabilization was achieved with excess calcium addition (6 g per 10 g of air-dried treatment residual) [34]. Montes-Hernande et al. [35] investigated the removal of oxyanions such as arsenic from an aqueous solution using carbonation of Ca(OH)2 under moderate pressure (PCO2 = 20 bar) and temperature (30 °C). They placed one liter of high-purity water, 20 g of commercial portlandite Ca(OH)2, 0 to 250 mg of sodium selenite pentahydrate Na2SeO3·5(H2O), sodium selenate Na2SeO4, sodium acid arsenate heptahydrate Na2HAsO4·7(H2O), and monosodium phosphate NaH2PO4 in a titanium reactor. The solid particles were immediately dispersed by mechanical stirring (400 rpm) at 30 °C. Then, a 20 bar of CO2 was injected in the reactor. At the end of the experiment, the reaction cell was rapidly depressurized for about 5 min and the autoclave was disassembled. Then, they reported that the Ca(OH)2 carbonation reaction allowed for the successful removal of selenite (>90%), arsenate (>78%), and phosphate (almost 100%) from synthetic solutions [35]. Olyaie et al. [36] evaluated CaO2 nanoparticles synthesized for removing As (III) from contaminated water. CaO2 is one of the oxidants and decomposes in high humidity to produce Ca(OH)2 and H2O2. The diameter of CaO2 nanoparticle was 15–25 nm. The removal efficiency was enhanced by increasing the CaO2 nanoparticles’ dosage and reaction time. Up to 88% removal efficiency for arsenic was obtained by nanoparticles’ dosage of 40 mg/L at time equal to 30 min and pH 7. However, decreased by increasing arsenic concentration and pH [36]. Hu et al. [37] investigated the effect of calcium on arsenate removal by electrocoagulation with aluminum electrode. The used calcium salt was CaCl2. Their test conditions were an initial arsenic concentration of 10 mM (i.e., approximately 750 mg/L as As), an initial calcium addition concentration of 0–2 mol ratio to the initial arsenic concentration (i.e., 0–800 mg/L as Ca), and a reaction time of 40 min. The addition of calcium salt dramatically improved the removal efficiency of As(V). They concluded that this was due to calcium ions neutralizing the negative surface charge of the precipitates and increasing the As-O binding energy. In addition, they reported that the addition of calcium also prevented the formation of a deposit layer on anode surface which caused an increase of applied potential and a decrease in the concentration of dissolve Al [37].
As summarized above, Mg- and Ca-based adsorbents are expected to be so effective for As removal, as well as Fe-based adsorbents and so on. Furthermore, Mg and Ca compounds, which are the base materials of Mg- and Ca-based adsorbents, are abundantly available and are generally cheaper than Fe and Al. In addition, Mg and Ca components that may leach from Mg-based and Ca-based adsorbents are not harmful to humans or animals. However, the As-removal performance and/or the environmental stability of the adsorbents may deteriorate when the base materials leach from the system. Arsenic removal using individual Mg-based and Ca-based adsorbents has been studied by many researchers [30,31,32,33,34,35,36,37], but there has been little research on As removal using various combinations of Mg-based and Ca-based adsorbents. Furthermore, preliminary results with respect to the present study suggest the possibility of inhibiting the leaching of base materials by combining specific Mg- and Ca-based adsorbents. Investigating how As removal changes with the combination of different types of adsorbents will provide important guidance for designing novel treatments with high performance. This study aimed to find improved sustainable adsorbent combinations with both high As-removal performance and high environmental stability. The Mg- and Ca-based adsorbents were compared individually and in combination with each other in a full factorial experiment. Finally, improvements in the As-removal performance and environmental stability of the adsorbents using the combined-addition method were evaluated.

2. Materials and Methods

The reagents listed in this article were purchased from FUJIFILM Wako Pure Chemical Corporation (formerly Wako Pure Chemical Industries, Ltd., Osaka, Japan), unless specified otherwise.

2.1. Mg- and Ca-Based Adsorbents

In this study, to clarify the effects of arsenic-removal performance and base-materials leaching behavior due to the difference in the chemical compositions of the adsorbents, pure analytical grade powder reagents were used without processing, as adsorbents. The powder reagents of Mg and Ca oxides, hydroxides, and carbonates were used as Mg-based (MgO, Mg(OH)2, and MgCO3) and Ca-based (CaO, Ca(OH)2, and CaCO3) adsorbents. The measured Mg content αMg (%), the measured Ca contents αCa (%), the reagent purity (obtained from αMg and αCa) P (%), the median particle size Dp50 (μm), and the Brunauer–Emmett–Teller (BET) surface area SBET (m2/g) are shown in Table S1. The data on the table, except for CaCO3, were obtained from a previous study [38].
The αCa value of CaCO3 was determined by dissolving CaCO3 in 1 M HCl and then measuring Ca using ICP-AES (SII SPS3500DD). The Dp50 value of CaCO3 was determined using a particle size analyzer (Microtrac HRA 9320-X100, Nikkiso Co., Ltd., Tokyo, Japan). The SBET value of CaCO3 was determined using a specific surface area measurement instrument (BELSOOP-miniX, MicrotracBEL Corp., Osaka, Japan).

2.2. Synthetic As(V)-Contaminated Water

Powdered disodium hydrogen arsenate heptahydrate (Na2HAsO4·7H2O, 99%) was dissolved in deionized water to create our As(V) stock solution (2000 mg-As/L). One part of the stock solution was diluted with deionized water to prepare a 1 or 10 mg-As/L solution. This solution was used as synthetic As(V)-contaminated water after adjusting the pH to near neutral using hydrochloric acid. The initial pH (pH0) was taken as that of the synthetic As(V)-contaminated water immediately before adding the adsorbent. The initial As concentration (CAS0 in mg/L) was taken as that in the synthetic As(V)-contaminated water immediately before adding the adsorbent, and was either 1 or 10 mg/L. The pH meter and electrode used in this study were LAQUA F-72 and a Micro ToupH Electrode 9618S-10D, respectively, manufactured by HORIBA, Ltd. (Kyoto, Japan). The As in the solution was quantified by ICP-MS (Agilent 7700X).

2.3. As-Removal Tests

As-removal tests were classified as either single-addition tests, which consisted of one type of adsorbent, or combined-addition tests, which consisted of two types of adsorbents.
One or two types of the adsorbents mentioned in Section 2.1 were weighted into a 50-mL polypropylene centrifuge tube. The amount of each adsorbent to be weighed was to become a set value of adsorbent addition concentration when 50 mL of the liquid was added. The centrifuge tube containing the adsorbent was sealed immediately after adding 50 mL of the above synthetic As(V)-contaminated water and shaken in a constant-temperature shaker (approximately 180 rpm at 20–25 °C). The tube was centrifuged after shaking for 24 h. The supernatant was filtered through a syringe filter with a pore diameter of 0.45 μm and collected in a polypropylene vessel. The pH of the filtrate (treated water) was immediately measured and taken as the final pH (pHf). As, Mg, and Ca in the treated water were quantified using the ICP-MS and the ICP-AES, respectively, and were denoted as CAS, CMg, and CCa, respectively.
The adsorbent addition concentration in the As-removal tests was set on a mass basis. WAd was the amount of adsorbent added to the synthetic As(V)-contaminated water in g, and V was the liquid volume (in L) of the synthetic As-contaminated water.
In the single-addition tests of one type of adsorbent, the adsorbent addition concentration, WAd/V (g/L), was set to 0.2 and 0.4 g/L.
In the combined-addition tests of two types of adsorbents, the mass-based total adsorbent addition concentration, ΣWAd/V (g/L), was set to 0.4 g/L (each 0.2 g/L).

2.4. Definitions of Mg- and Ca-Residual Ratios

As some of the constituents of the adsorbent can leach into the liquid, the amount of adsorbent remaining as a solid is reduced from the initial amount. As the Mg and Ca components are leached out from the Mg-based and Ca-based adsorbents, the amounts of Mg and Ca remaining as a solid in the liquid are calculated as the Mg-residual ratio RMg [%] and RCa [%], using the Equations (1) and (2).
RMg = 100 − (CMg × 1000)/[WAd/V × (αMg/100)] × 100.
RCa = 100 − (CCa × 1000)/[WAd/V × (αCa/100)] × 100.

3. Results

3.1. Single Addition of One Type of Adsorbent

Table S2 shows the results obtained from the single-addition tests with one type of adsorbent at CAS0 = 1 mg/L. To confirm the reproducibility of the experimental data, test nos. 1–6 were conducted three times each, the results of which are presented in Table S2. The table shows average values obtained from each test conducted thrice. In addition, Table S3 shows the relative standard errors ε [%] for all six tests in Table S2. The standard errors of both pH0 and CAS0 for each test conducted thrice are zero, because the synthetic As(V)-contaminated water used in the tests were the same. The values of ε for WAd/V, were within 1.2%, which can be attributed to the accuracy of weighing the adsorbent. The values of ε for pH0, CAS, CMg, and CCa were within 0.1%, 5%, 4%, and 3%, respectively. These results indicate that the reproducibility of the experimental data was good.
As shown in Table S2, regardless of WAd/V, the magnitude of the relationship of pHf was CaCO3 < Mg(OH)2 < MgCO3 < MgO < Ca(OH)2 = CaO. There was no clear difference in pHf for adsorbents other than CaO and Ca(OH)2 depending on WAd/V, but the pHf for CaO and Ca(OH)2 clearly increased with increasing WAd/V. At both 0.2 and 0.4 g/L of WAd/V, the Mg-based adsorbents exhibited an improved As-removal performance compared with the Ca-based adsorbents. However, the magnitude of the relationship of the As-removal performance of the adsorbent differed only slightly depending on WAd/V. The magnitude of the relationship of CAS at WAd/V = 0.2 g/L was Mg(OH)2 < MgO < MgCO3 < Ca(OH)2 < CaO < CaCO3. The magnitude relationship of CAS at WAd/V = 0.4 g/L was MgO < Mg(OH)2 < MgCO3 < CaO < Ca(OH)2 < CaCO3. Regardless of WAd/V, the magnitude of the relationships of CMg and CCa were Mg(OH)2 < MgO < MgCO3 and CaCO3 < Ca(OH)2 < CaO, respectively.
Table S4 shows the results obtained from the single-addition tests with one type of adsorbent at CAS0 = 10 mg/L. The tendencies of pHf, CMg, and CCa at CAS0 = 10 mg/L were similar to those at CAS0 = 1 mg/L, except for the following two points: (1) the pHf for CaCO3, as with other Ca-based adsorbents, clearly increased with increasing WAd/V; (2) CCa was slightly higher for Ca(OH)2 than for CaO at WAd/V = 0.4 g/L. In contrast, the tendency of CAS was significantly different from that at CAS0 = 1 mg/L, except for the highest CAS for CaCO3. At WAd/V = 0.2 g/L, the magnitude of the relationship of CAS was CaO < MgO < Mg(OH)2 < MgCO3 < Ca(OH)2 < CaCO3. At WAd/V = 0.4 g/L, the magnitude of the relationship of CAS was Ca(OH)2 < CaO < MgO < Mg(OH)2 < MgCO3 < CaCO3.

3.2. Combined Addition of Two Types of Adsorbents

Tables S5 and S6 show the results obtained from the combined-addition tests of two types of adsorbents at CAS0 = 1 and 10 mg/L, respectively.
Regardless of CAS0, the pHf was higher in the combined-addition tests between the Ca-based adsorbents than between the Mg-based adsorbents. In the combined-addition tests of one Mg-based with one Ca-based adsorbent, pHf tended to become relatively high with CaO or Ca(OH)2, but relatively low with CaCO3.
The CMg in the combined addition-tests of two different types of the Mg-based adsorbents did not sum to the total of the CMg in their single-addition tests and appeared to be closer to the higher values between the single tests. The CMg tended to be lower in the combined additions of the Mg-based adsorbents with CaO or Ca(OH)2 than in the single additions of each Mg-based adsorbent. The CMg in the combined additions of the Mg-based adsorbents with CaCO3 were not significantly different from those in the single additions of each Mg-based adsorbent.
The CCa in the combined addition-tests of two different types of the Ca-based adsorbents appeared to be close to the sum of the CCa in their single-addition tests and appeared somewhat higher in CaO–CaCO3. There was no significant difference in CCa between the combined addition of CaO or Ca(OH)2 with MgO or Mg(OH)2 and the single additions of each Ca-based adsorbent. In contrast, the CCa in the combined additions of the Ca-based adsorbents with MgCO3 tended to be lower than that in the single additions of one type of each Ca-based adsorbent. In addition, the CCa in the combined additions of CaCO3 and the Mg-based adsorbents were lower than those in the single addition of CaCO3.
Moreover, in contrast, the tendency of the CAS differed depending on CAS0. At CAS0 = 1 mg/L, the CAS was significantly lower in the combined-addition tests of MgO-Mg(OH)2, MgCO3-Ca(OH)2, MgCO3-CaO, and Mg(OH)2-CaO. At CAS0 = 10 mg/L, the CAS was significantly lower in the combined-addition tests of MgCO3-Ca(OH)2, MgCO3-CaO, Mg(OH)2-Ca(OH)2, and CaO-Ca(OH)2.

4. Discussion

The effects of improving As-removal performance and those of inhibiting Mg- and Ca-leaching via combined addition have been discussed below based on the data obtained from the As-removal tests conducted in this study.

4.1. As-Removal Performance

4.1.1. As-Removal Ratio

The As-removal ratio, RAS [%], was calculated as:
RAS = (CAS0CAS)/CAS0 × 100.
RAS values are summarized in Table 1, Table 2 and Table 3. Table 1 shows RAS for the single-addition As-removal tests.
From Table 1, it is clear that RAS did not necessarily double when the adsorbent addition concentrations were doubled. Although CaCO3 could not remove As even if the adsorbent addition concentration was increased, the RAS of the other adsorbents increased as the adsorbent addition concentration increased. Some adsorbents, such as CaO, more than doubled their RAS when the adsorbent concentrations were only doubled. Overall, the RAS was higher for Mg-based adsorbents at CAS0 = 1 mg/L and higher for Ca-based adsorbents (excluding CaCO3) at CAS0 = 10 mg/L. In general, the surface area of adsorbent can be an important parameter related to its adsorption capacity. The magnitude of SBET is CaCO3 < CaO < MgO < Ca(OH)2 < Mg(OH)2 < MgCO3, as shown in Table S1. Hence, the magnitude relationship of RAS among the adsorbents did not correspond to that of SBET. Section 1 introduced previous studies on Mg-based and Ca-based adsorbents [30,31,32,33,34,35,36,37], but since the experimental conditions differed among their experiments, it is difficult to directly determine the order of superiority among their adsorbents. However, Yu et al. [32] compared two MgO and two hydromagnesites (i.e., MgCO3) under the same experimental conditions. They reported that the As adsorption capacity of MgO was much higher than that of MgCO3, but there was no significant difference in specific surface area among them. This superiority in As adsorption between MgO and MgCO3 is consistent with our experimental results. Therefore, it is believed that the arsenic-removal performance is more strongly related to the chemical composition of the adsorbent than to the surface area.
Table 2 and Table 3 show RAS for the combined addition of two types of adsorbents obtained from As-removal tests with the mass-based adsorbent addition concentration at CAS0 = 1 and 10 mg/L, respectively. For convenience, the results of single additions at WAd/V = 0.4 g/L are also included in Table 2 and Table 3. In addition, each RAS of the combined additions is shown in Figure 1, based on the data in Table 2 and Table 3. Figure 1a,b correspond to CAS0 = 1 and 10 mg/L, respectively.
At CAS0 = 1 mg/L, the RAS of the combined additions of MgO-Mg(OH)2, MgCO3-Ca(OH)2, MgCO3-CaO, MgO-MgCO3, Mg(OH)2-CaO, MgO-MgO, Mg(OH)2-Mg(OH)2 and Mg(OH)2-Ca(OH)2 were high (>90%). At CAS0 = 10 mg/L, the RAS of the combined addition of MgCO3-Ca(OH)2 was the highest (>80%) and followed by those of MgCO3-CaO, Ca(OH)2-Ca(OH)2, and CaO-Ca(OH)2 (>60%).
From the above, the As-removal performance of the combined addition of MgCO3-Ca(OH)2 was the highest at both 1 and 10 mg/L of CAS0.

4.1.2. Effects of Combined Addition on As-Removal Performance

When multiple adsorbents are added together, the RAS was typically not equal to the sum of the individual adsorbents RAS values. This apparent combined-adsorbent synergistic effect was evaluated using the following method. The higher of the two single-addition RAS values for each adsorbent of a combined test was subtracted from the RAS in the combined-addition test. The obtained difference was denoted as ΔRAS.
The ΔRAS values are shown in Table 4 for CAS0 = 1 mg/L and Table 5 for CAS0 = 10 mg/L. Similar to Table 2 and Table 3, the results from the single-additions, WAd/V = 0.4 g/L tests are included. Similar to Figure 1, each ΔRAS of the combined additions is shown in Figure 2, based on the data in Table 4 and Table 5. Figure 2a,b correspond to CAS0 = 1 and 10 mg/L, respectively.
At CAS0 = 1 mg/L, the ΔRAS of the combined additions of MgCO3-Ca(OH)2 and MgCO3-CaO were the highest (>60%). At CAS0 = 10 mg/L, the ΔRAS of the combined addition of MgCO3-Ca(OH)2 was the highest (>70%). On the other hand, the ΔRAS of the combined addition of Mg(OH)2-CaCO3 at CAS0 = 1 mg/L and those of MgO-CaO and MgO-CaCO3 at CAS0 = 10 mg/L were significantly negative (<−5%), indicating that the As-removal performance of the combined addition was lower than that of each single addition.
From the above, it was found that many combined additions, especially MgCO3-CaO and MgCO3-Ca(OH)2, improved As-removal performance; however, some combined additions of the Ca-based adsorbents, MgO and -Mg(OH)2, decreased the As-removal performance. In the former two combined-additions (MgCO3-CaO and MgCO3-Ca(OH)2), it is considered that MgCO3 released Mg2+ and CO32−, and CaO or Ca(OH)2 released Ca2+ and OH-, followed by reformations of Mg(OH)2 and CaCO3. Hence, it is suggested that the As-removal performance improved because the As components were taken in during the formations of Mg(OH)2 and CaCO3 (i.e., co-precipitation phenomenon).

4.2. Mg-Leaching Behavior

4.2.1. Mg-Residual Ratio

RMg obtained from the As-removal tests in this study are shown in Table 6, Table 7 and Table 8. However, it should be noted that the values of RMg obtained from these calculations include the resolidified portion of Mg once leached out.
Table 6 shows RMg for the single addition of one type of adsorbent obtained from As-removal tests.
For all the Mg-based adsorbents, the RMg of the higher adsorbent addition concentration were higher than that of the lower adsorbent addition concentration. Both the RMg of MgO and Mg(OH)2 were very high (>90%) in the range of the experimental conditions.
Table 7 and Table 8 show RMg for the combined addition of two types of adsorbents obtained from As removal tests at CAS0 = 1 and 10 mg/L, respectively. For convenience, the results in the single additions of WAd/V = 0.4 g/L have also been included in Table 7 and Table 9. In addition, each RMg of the combined additions is shown in Figure 3, based on the data in Table 7 and Table 8. Figure 3a,b correspond to CAS0 = 1 and 10 mg/L, respectively.
There was no difference in the tendency of RMg depending on CAS0. Most of the combined additions had an RMg of >90%. Particularly, the RMg of Mg(OH)2-CaO or -Ca(OH)2, and MgO-CaO or -Ca(OH)2 were almost 100%. On the other hand, the RMg of MgCO3-CaCO3 was the lowest (58.5% at CAS0 = 1 mg/L and 64.6% at CAS0 = 10 mg/L).

4.2.2. Effects of Combined Addition on Mg-Leaching Behavior

Even if the Mg-residual ratio was the same, the Mg leached amount differed depending on the type of Mg-based adsorbent. Therefore, to evaluate the effects of the combined addition on the Mg-leaching behavior, it was more appropriate to compare the amount of change in CMg. Then, the higher CMg in the single-addition test (WAd/V = 0.2 g/L) of the two types of adsorbents used in the combined-addition test (ΣWAd/V = 0.4 g/L) was subtracted from the CMg in the combined-addition test. The obtained difference was denoted as ΔCMg. The lower the value of ΔCMg, the higher the effects of inhibiting Mg-leaching.
The ΔCMg is shown in Table 9 for CAS0 = 1 mg/L and Table 10 for CAS0 = 10 mg/L, respectively. Similar to Figure 2, each ΔCMg of the combined additions is shown in Figure 4, based on the data in Table 9 and Table 10. Figure 4a,b correspond to CAS0 = 1 and 10 mg/L, respectively.
There was no significant difference in the tendency of ΔCMg depending on CAS0. The ΔCMg of MgCO3-CaO and -Ca(OH)2 were the lowest followed by MgO-CaO and -Ca(OH)2. For Mg(OH)2-CaO and -Ca(OH)2, the leaching of Mg was slightly inhibited. In contrast, the combined additions of the Mg-based adsorbents with CaCO3 had almost no effect of inhibiting the leaching of Mg. In addition, no clear increase in the amount of Mg-leaching was observed even with the combinations between Mg-based adsorbents.
From the above, combining CaO or Ca(OH)2 with the Mg-based adsorbents was shown to inhibit Mg-leaching. The effects of inhibiting Mg-leaching by CaO and Ca(OH)2 were similar, and the magnitude of the effects was Mg(OH)2 < MgO < MgCO3.

4.3. Ca-Leaching Behavior

4.3.1. Ca-Residual Ratio

RCa obtained from the As-removal tests in this study are shown in Table 11, Table 12 and Table 13. However, it should be noted that the values of RCa obtained from these calculations include the resolidified portion of Ca once leached out, similar to RMg for the Mg-based absorbent.
Table 11 shows RCa for the single addition of one type of adsorbent obtained from As-removal tests.
Regardless of CAS0, the RCa of CaCO3 exceeded 90%, but the RCa of CaO and Ca(OH)2 showed considerably low values. Even if the adsorbent addition concentration was doubled, the RCa of Ca(OH)2 and CaCO3 hardly changed. In contrast, the RCa of CaO nearly doubled when WAd/V was doubled.
Table 12 and Table 13 show RCa for the combined additions of two types of adsorbents obtained from As-removal tests for CAS0 = 1 and 10 mg/L, respectively. For convenience, the results in the single additions of WAd/V = 0.4 g/L have also been included in Table 12 and Table 13, respectively. Similar to Figure 3, each RCa of the combined additions is shown in Figure 5, based on the data in Table 12 and Table 13. Figure 5a,b correspond to CAS0 = 1 and 10 mg/L, respectively.
There was no significant difference in the tendency of RCa depending on CAS0. However, overall, RCa tended to be slightly higher at CAS0 = 10 mg/L than at CAS0 = 1 mg/L. In combinations of CaCO3 with the adsorbents other than CaO and Ca(OH)2, the RCa significantly exceeded 90%. The RCa in most of the combinations of CaO and of Ca(OH)2 were low overall; however, those with MgCO3 were relatively high. The RCa in the combinations of Ca(OH)2, excluding those with MgCO3, were considerably lower than those in the combinations of CaO and of CaCO3.

4.3.2. Effects of Combined Addition on Ca-Leaching Behavior

Similar to Mg, even if the Ca-residual ratio is the same, the amount of Ca leached differs depending on the type of the Ca-based adsorbent used. Therefore, to evaluate the effects of the combined addition on the Ca-leaching behavior, it is considered more appropriate to compare the amount of change in CCa. Then, the higher CCa in the single-addition test (WAd/V = 0.2 g/L) of the two types of adsorbents used in the combined-addition test (ΣWAd/V = 0.4 g/L) is subtracted from the CCa in the combined-addition test. The obtained difference was denoted as ΔCCa. The lower the value of ΔCCa, the higher the effects of inhibiting the leaching of Ca.
The ΔCCa with the mass-based adsorbent addition concentration is shown in Table 14 for CAS0 = 1 mg/L and 15 for CAS0 = 10 mg/L, respectively. Similar to Figure 4, each ΔCCa of the combined additions is shown in Figure 6, based on the data in Table 14 and Table 15. Figure 6a,b correspond to CAS0 = 1 and 10 mg/L, respectively.
There was no significant difference in the tendency of ΔCCa depending on CAS0. The ΔCCa of Ca(OH)2-MgCO3 was the lowest. The ΔCCa of CaO-MgCO3, -Mg(OH)2, and -MgO were the next lowest. In contrast, a clear increase in the amount of Ca-leaching was observed with the combinations between Ca-based adsorbents other than CaCO3.
From the above, combining MgCO3 with the Ca-based adsorbents was shown to inhibit Ca-leaching. It was not significantly different in the effects of inhibiting Ca-leaching by MgCO3 between CaO and Ca(OH)2. CaCO3 also seemed to inhibit Ca-leaching by combining with MgCO3; however, this is not clear because the CCa values were very low.

4.4. Mechanism of Inhibiting Mg- and Ca-Leaching

In this section, we have provided some brief considerations regarding the mechanisms of inhibiting Mg- and Ca-leaching by combining with Mg-based and Ca-based adsorbents.
First, the chemical reactions when each of the components are leached from the Mg-based and Ca-based adsorbents are shown below.
MgO (s) + H2O (l) ←→ Mg2+ (aq) + 2OH (aq)
Mg(OH)2 (s) ←→ Mg2+ (aq) + 2OH (aq)
MgCO3 (s) ←→ Mg2+ (aq) + CO32− (aq)
CaO (s) + H2O (l) ←→ Ca2+ (aq) + 2OH (aq)
Ca(OH)2 (s) ←→ Ca2+ (aq) + 2OH (aq)
CaCO3 (s) ←→ Ca2+ (aq) + CO32− (aq)
In reality, the carbonate ion in (6) and (9) undergoes the following chemical equilibrium reactions, which depend on pH.
CO32− (aq) + H2O (l) ←→ HCO3 (aq) + OH (aq)
HCO3 (aq) + H2O (l) ←→ H2CO3 (aq) + OH (aq)
The chemical reactions related to the inhibition of Mg- and Caleaching can be explained by the combination of the above chemical reactions.

4.4.1. Chemical Reactions Involved in Inhibiting Mg-Leaching

In Section 4.2, the combined additions of the Mg-based adsorbents with CaO or Ca(OH)2 were shown to inhibit Mg-leaching. Mg2+ on each right side of Equations (4)–(6) reacts with OH- on each right side of Equations (7) and (8) to produce Mg(OH)2.
Mg2+ (aq) + 2OH (aq) ←→ Mg(OH)2 (s)
Therefore, one of the mechanisms for inhibiting Mg-leaching by the above-mentioned combined addition is the resolidification of the leached Mg owing to the production of Mg(OH)2. In addition, the values of pHf were higher in the combined addition of CaO or Ca(OH)2 than in the single additions of the Mg-based adsorbents; thus, the Mg(OH)2 was more likely to be produced. In contrast, as the values of pHf in the combined addition with CaCO3 added were almost the same as those in the single additions of the Mg-based adsorbents, indicating that Mg(OH)2 could not be produced.

4.4.2. Chemical Reactions Involved in Inhibiting Ca-Leaching

In Section 4.3, the combined additions of the Ca-based adsorbents with MgCO3 were shown to inhibit Ca-leaching. Ca2+ on each right side of Equations (7)–(9) reacts with CO32− on each right side of Equation (6) to produce CaCO3.
Ca2+ (aq) + CO32− (aq) ←→ CaCO3 (s)
Therefore, one of the mechanisms for inhibiting Ca-leaching by the above-mentioned combined addition is the resolidification of the leached Ca due to production of CaCO3. Ca(OH)2 may also be considered a candidate for resolidified substances. However, as the pHf is lower in the combined addition with MgCO3 than in the single additions of CaO or Ca(OH)2, it is considered unlikely that Ca(OH)2 was produced.
In addition, compounds such as (Mg)p(Ca)q(OH)r(CO3)s (p, q, r and s are positive numbers) may be produced; it is thus necessary to perform highly accurate X-ray analysis and detailed chemical equilibrium calculation in the future.

4.5. Mechanism of As Adsorption

4.5.1. Dissolved Forms of Arsenic in Solution

The dissolved forms of As(V) in solutions are represented by the following dissociation reaction formulas for arsenic acid:
H3AsO4 (aq) ←→ H2AsO4 (aq) + H+ (aq)
H2AsO4 (aq) ←→ HAsO42− (aq) + H+ (aq)
HAsO42− (aq) ←→ AsO43− (aq) + H+ (aq)
where pKa1 = 2.24, pKa2 = 6.96, and pKa3 = 11.50 (25 °C) [39].
The value of pH0 was 6.91–7.32 (see Tables S2 and S4–S6) and pKa1 << pH0 << pKa3, so the abundances of H3AsO4 and AsO43− were considered to be extremely small and negligible. The value of pKa2 was applied to Equation (15). Then, after substituting the pH0 value, the value of (HAsO42−)/(H2AsO4) = 10 exp (pH0 − pKa2) was calculated to be 0.89–2.29. Based on the results, the main dissolved forms of As in the simulated As(V)-contaminated water before adding the adsorbents were presumed to be H2AsO4 and HAsO42−.
On the other hand, the value of pHf was 9.45 to 12.05, and differed greatly depending on the type and combination of adsorbents (see Tables S2 and S4–S6). pKa2 << pHf, so the abundances of H3AsO4 and H2AsO4 were considered to be extremely small and negligible. In addition, in the cases of the single addition, the values of pHf for CaCO3, Mg(OH)2, MgCO3, MgO, Ca(OH)2, and CaO were 9.45–9.71, 10.39–10.48, 10.59–10.68, 10.81–10.94, 11.72–12.05, and 11.80–12.05, thus the values of (AsO43−)/(HAsO42−) = 10 exp (pHf − pKa3) were <<0.1, <0.1, 0.12–0.15, 0.20–0.26, 1.66–3.55, and 2.00–3.55, respectively. Therefore, the main dissolved forms of As in the treated water were inferred to be HAsO42− for MgO, Mg(OH)2, MgCO3, and CaCO3, and then AsO43− for CaO and Ca(OH)2.
However, as the dissolved form of As would change accordingly as the pH of the solution increases with the leaching (dissolution) of the base material components from the adsorbents, any form of As that may be present at the pH range of pH0 to pHf could react with the adsorbent. In addition, even in the case of the combined addition, the idea regarding the dissolved form of As is the same as in the case of the single addition described above.

4.5.2. Reactions of Adsorption, Precipitation, and Co-Precipitation of As

It is considered that a part of each adsorbent is dissolved in the solution by the reaction of Equations (4)–(9) shown in Section 4.4, and the adsorbent surface remaining as a solid phase is also hydrated to form Solid-Me-OH, where Me is Mg or Ca.
First, assuming H2AsO4 as the adsorbed species, the reaction with the adsorbent is speculated below.
Solid-Me-OH (s) + H2AsO4 (aq) ←→ Solid-Me-O-AsO(OH)2 (s) + OH (aq)
Equation (17) represents the chemical adsorption reaction due to the ion exchange between H2AsO4 and OH.
Additionally, the adsorption reactions after the hydroxyl groups on the surface of the adsorbent dissociate to form Solid-Me+ are considered:
Solid-Me+ (s) + H2AsO4 (aq) ←→ Solid-Me-O-AsO(OH)2 (s)
Equation (18) represents the electrostatic chemical adsorption reaction.
In both Equations (17) and (18), H2AsO4 on the left sides can be replaced with HAsO42− or AsO43−. In those cases, Solid-Me-O-AsO(OH)2 on the right sides in Equations (17) and (18), are replaced by Solid-Me-O-AsO(OH)O and Solid-Me-O-AsO(O)2. However, it is difficult to identify the actual adsorbed arsenic acid species as mentioned in Section 4.5.1 and also to differentiate between Equations (17) and (18).
Furthermore, a reaction in which released Mg2+ or Ca2+, as in Equations (4)–(9), binds with arsenic acid species to form and precipitate arsenate species is also conceivable. For example, assuming AsO43− as the reacting species, the precipitation reaction of arsenate species is described as:
3Me2+ (aq) + 2AsO43− (aq) ←→ Me3(AsO4)2 (s)
However, the formation of arsenate species also significantly depends on the concentration of each dissolved component and pH; thus, the possibility of the formation should be verified by chemical equilibrium calculations.
RAS for the combined addition of each MgCO3-CaO and MgCO3-Ca(OH)2 was much higher than that for the single addition of each MgCO3, CaO and Ca(OH)2 as described in Section 4.1. This is due to As adsorption on MgCO3, CaO, and Ca(OH)2 individually but also to As being incorporated and co-precipitated when Mg(OH)2 and CaCO3 are produced, as in Equations (12) and (13).

4.6. Comprehensive Evaluation

To summarize what has been described above, as evaluated in terms of both As-removal performance and leaching of the base material components from the adsorbent, the single addition or combined addition of the adsorbents, which would be highly evaluated comprehensively, are as follows.
At CAS0 = 1 mg/L, the most performant strategies are the single addition of MgO or Mg(OH)2, or the combined additions of Mg(OH)2-CaO, MgCO3-CaO or MgCO3-Ca(OH)2. At CAS0 = 10 mg/L, the most performant strategies are MgCO3-Ca(OH)2 or MgCO3-CaO. Therefore, if the As(V)-contaminated water may have a wide concentration range, MgCO3-Ca(OH)2 or MgCO3-CaO are the recommended adsorbent compositions.
Since Fe-based adsorbents are expensive, regeneration treatment with Ca-based adsorbents has been suggested [34], which can lead to increased operational complexity and cost. In addition, it has been pointed out that when Fe(II) exists on the surface of Fe-based adsorbents, the adsorbed As(V) may be reduced to highly toxic As(III) and eluted [25]. Such a reduction reaction would not occur for Mg-based and Ca-based adsorbents. Furthermore, adsorbents doped with cobalt (one of transition elements) have problems with cobalt leaching [29], which may lead to health risks. On the other hand, Mg and Ca components that may leach from Mg-based and Ca-based adsorbents are not harmful to humans or animals. Since it is necessary to select the optimum adsorbent according to the contamination state, contamination factors, purification conditions, etc., it would be better to list a wide variety of adsorbents as candidates in advance. This study reported the results of arsenic-removal tests with various combinations of Mg-based and Ca-based adsorbents, and it is hoped that the results of this research will be useful when selecting a combination of adsorbents according to the arsenic contamination state.
In this study, the As-removal tests used two types of adsorbents combined at an adsorbent addition concentration of 1:1 by mass ratio. In the near future, stoichiometric and chemical equilibrium studies should be conducted and the effect of inhibiting the leaching should be analyzed using the data obtained in this study. Additional tests on the molar ratio of the adsorbent addition concentration as variables are needed, and an optimum adsorbent mixing ratio should be derived. Furthermore, in future research, we also plan to investigate this process using “arsenite” rather than “arsenate”.

5. Conclusions

In this study, As-removal tests with the combined addition of Mg- and Ca-based adsorbents were systematically conducted for the purpose of improving the As-removal performance and inhibiting the leaching of base material components from adsorbents (i.e., improving the environmental stability of adsorbents). The results of the combined addition tests were compared to those of the single-addition tests with each adsorbent.
Many of the combined additions tested in this study, especially MgCO3-CaO and MgCO3-Ca(OH)2, are promising. Some combined additions of the Ca-based adsorbents, MgO and -Mg(OH)2, decreased the As-removal performance. The As-removal performance of the combined addition of MgCO3-Ca(OH)2 was the highest at both 1 and 10 mg/L of CAS0. It was clarified that the combined additions of the Mg-based adsorbents with CaO or Ca(OH)2 inhibited Mg-leaching. The effects of inhibiting Mg-leaching by CaO and Ca(OH)2 were similar but depended on the Mg species, with Mg(OH)2 < MgO < MgCO3. One of the mechanisms for inhibiting Mg-leaching via these combined additions was considered to be the resolidification of the leached Mg owing to the production of Mg(OH)2. It was also clarified that the combined addition of CaO or Ca(OH)2 with MgCO3 inhibited the leaching of Ca. It was not significantly different in the effects of inhibiting the Ca-leaching by MgCO3 between CaO and Ca(OH)2. One of the mechanisms for inhibiting Ca-leaching by these combined additions was the resolidification of the leached Ca owing to the production of CaCO3. The improvement of the As-removal ratio for the combined addition of each MgCO3-CaO and MgCO3-Ca(OH)2 was considered to be caused by the incorporation and co-precipitation with As when Mg(OH)2 and CaCO3 were produced, in addition to As adsorption on each adsorbent. From the viewpoints of both As-removal performance and the environmental stability of the adsorbents, MgCO3-Ca(OH)2 or MgCO3-CaO are recommended as improved sustainable adsorbent combinations that can be effectively applied over a wide range of As concentrations.
Since the As-removal tests in this study were performed at only two initial As-concentrations and one initial pH, we were not possible to determine the optimal range for As-removal performance. Although the combined-addition tests in this study were performed at only an adsorbent addition concentration of 1:1 by mass ratio, in order to derive the optimum mixing ratio of the adsorbents, it will be necessary to conduct additional tests with varying the adsorbent mixing ratio as a parameter. Nevertheless, this study demonstrated that the combined addition of specific Mg-based and Ca-based adsorbents is possible to improve the As-removal performance and also inhibit the leaching of the matrix component from the adsorbents. The results of this study are expected to increase the options for using Mg-based and Ca-based adsorbents for arsenic contamination treatment.

Supplementary Materials

The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/su15054689/s1, Table S1: characteristics of the adsorbents where α is the measured content, P is the reagent purity, Dp50 is the median particle size, and SBET is the Brunauer–Emmett–Teller (BET) surface area; Table S2: target and measured values for the CAS0 = 1 mg/L, single-addition tests where one type of adsorbent was employed at a time to assess As removal; Table S3: relative standard errors for test nos. 1–6 in Table S2; Table S4: target and measured values for the CAS0 = 10 mg/L, single-addition tests where one type of adsorbent was employed at a time to assess As removal; Table S5: target and measured values for the CAS0 = 1 mg/L, combined-addition tests where two types of adsorbents were added at a time to assess As removal; Table S6: target and measured values for the CAS0 = 10 mg/L, combined-addition tests where two types of adsorbents were added at a time to assess As removal.

Author Contributions

Conceptualization, H.S.; methodology, H.S. and J.H.; formal analysis, H.S. and J.H.; investigation, T.O. and H.S.; resources, H.S., M.Z., and J.H.; data curation, T.O. and H.S.; writing—original draft preparation, H.S. and T.O.; writing—review and editing, H.S., T.O., M.Z., J.H. and Y.K.; supervision, H.S. and M.Z.; project administration, M.Z. and Y.K.; funding acquisition, M.Z., Y.K., and H.S. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Data that support the findings of this study are available from the corresponding authors upon reasonable request.

Acknowledgments

We are deeply grateful to Norihisa Fukaya (Interdisciplinary Research Center for Catalytic Chemistry, AIST) for measuring the BET specific surface area of CaCO3.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. RAS for combined-addition at (a) CAS0 = 1 mg/L and (b) CAS0 = 10 mg/L. RAS = (CAS0CAS)/CAS0 × 100.
Figure 1. RAS for combined-addition at (a) CAS0 = 1 mg/L and (b) CAS0 = 10 mg/L. RAS = (CAS0CAS)/CAS0 × 100.
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Figure 2. ΔRAS for combined-addition at (a) CAS0 = 1 mg/L and (b) CAS0 = 10 mg/L. ΔRAS = (the combined-addition RAS) − (the higher of the two single-addition RAS).
Figure 2. ΔRAS for combined-addition at (a) CAS0 = 1 mg/L and (b) CAS0 = 10 mg/L. ΔRAS = (the combined-addition RAS) − (the higher of the two single-addition RAS).
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Figure 3. RMg for combined-addition at (a) CAS0 = 1 mg/L and (b) CAS0 = 10 mg/L. RMg = 100 – (CMg × 1000)/(WAd/V × (αMg/100)) × 100.
Figure 3. RMg for combined-addition at (a) CAS0 = 1 mg/L and (b) CAS0 = 10 mg/L. RMg = 100 – (CMg × 1000)/(WAd/V × (αMg/100)) × 100.
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Figure 4. ΔCMg for combined-addition at (a) CAS0 = 1 mg/L and (b) CAS0 = 10 mg/L. ΔCMg = [the combined-addition CMg] − [the higher of the two single-addition CMg].
Figure 4. ΔCMg for combined-addition at (a) CAS0 = 1 mg/L and (b) CAS0 = 10 mg/L. ΔCMg = [the combined-addition CMg] − [the higher of the two single-addition CMg].
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Figure 5. RCa for combined-addition at (a) CAS0 = 1 mg/L and (b) CAS0 = 10 mg/L. RCa = 100 – (CCa× 1000)/(WAd/V × (αCa/100)) × 100.
Figure 5. RCa for combined-addition at (a) CAS0 = 1 mg/L and (b) CAS0 = 10 mg/L. RCa = 100 – (CCa× 1000)/(WAd/V × (αCa/100)) × 100.
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Figure 6. ΔCCa for combined-addition at (a) CAS0 = 1 mg/L and (b) CAS0 = 10 mg/L. ΔCCa = (the combined-addition CCa) − (the higher of the two single-addition CCa).
Figure 6. ΔCCa for combined-addition at (a) CAS0 = 1 mg/L and (b) CAS0 = 10 mg/L. ΔCCa = (the combined-addition CCa) − (the higher of the two single-addition CCa).
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Table 1. As removal ratio (RAS) for single-addition As-removal tests.
Table 1. As removal ratio (RAS) for single-addition As-removal tests.
WAd/V
[g/L]
CAS0
[mg/L]
MgOMg(OH)2MgCO3CaOCa(OH)2CaCO3
0.2144.186.933.94.410.11.7
0.4198.197.553.615.719.92.1
0.21017.213.28.723.54.90.0
0.41031.326.218.851.760.60.0
unit [%].
Table 2. As removal ratio (RAS) for combined-addition As-removal tests at CAS0 = 1 mg/L.
Table 2. As removal ratio (RAS) for combined-addition As-removal tests at CAS0 = 1 mg/L.
ΣWAd/V = 0.4 g/LMgOMg(OH)2MgCO3CaOCa(OH)2CaCO3
MgO98.199.998.885.557.565.3
Mg(OH)299.997.588.499.190.079.2
MgCO398.888.453.699.799.933.3
CaO85.599.199.715.732.61.6
Ca(OH)257.590.099.932.619.913.6
CaCO365.379.233.31.613.62.1
unit [%].
Table 3. As removal ratio (RAS) for combined-addition As-removal tests at CAS0 = 10 mg/L.
Table 3. As removal ratio (RAS) for combined-addition As-removal tests at CAS0 = 10 mg/L.
ΣWAd/V = 0.4 g/LMgOMg(OH)2MgCO3CaOCa(OH)2CaCO3
MgO31.343.833.616.013.110.4
Mg(OH)243.826.221.038.058.112.2
MgCO333.621.018.863.983.79.8
CaO16.038.063.951.760.142.5
Ca(OH)213.158.183.760.160.68.2
CaCO310.412.29.842.58.20.0
unit [%].
Table 4. The combined-addition RAS minus the higher of the two single-addition RASRAS) for As-removal tests at CAS0 = 1 mg/L.
Table 4. The combined-addition RAS minus the higher of the two single-addition RASRAS) for As-removal tests at CAS0 = 1 mg/L.
ΣWAd/V = 0.4 g/LMgOMg(OH)2MgCO3CaOCa(OH)2CaCO3
MgO54.013.154.741.413.421.2
Mg(OH)213.110.61.512.23.2−7.7
MgCO354.71.519.665.766.0−0.7
CaO41.412.265.711.322.5−2.8
Ca(OH)213.43.266.022.59.83.5
CaCO321.2−7.7−0.7−2.83.50.4
unit [%].
Table 5. The combined-addition RAS minus the higher of the two single-addition RASRAS) for As-removal tests at CAS0 = 10 mg/L.
Table 5. The combined-addition RAS minus the higher of the two single-addition RASRAS) for As-removal tests at CAS0 = 10 mg/L.
ΣWAd/V = 0.4 g/LMgOMg(OH)2MgCO3CaOCa(OH)2CaCO3
MgO14.126.616.5−7.5−4.0−6.7
Mg(OH)226.613.07.814.545.0−1.0
MgCO316.57.810.140.475.01.1
CaO−7.514.540.428.236.619.0
Ca(OH)2−4.045.075.036.655.83.3
CaCO3−6.7−1.01.119.03.30.0
unit [%].
Table 6. Mg residual ratio (RMg) for single-addition As-removal tests.
Table 6. Mg residual ratio (RMg) for single-addition As-removal tests.
WAd/V
[g/L]
CAS0
[mg/L]
MgOMg(OH)2MgCO3CaOCa(OH)2CaCO3
0.2190.995.056.9---
0.4196.697.175.3---
0.21091.394.759.8---
0.41095.897.378.3---
unit [%].
Table 7. Mg residual ratio (RMg) for combined-addition As-removal tests at CAS0 = 1 mg/L.
Table 7. Mg residual ratio (RMg) for combined-addition As-removal tests at CAS0 = 1 mg/L.
ΣWAd/V = 0.4 g/LMgOMg(OH)2MgCO3CaOCa(OH)2CaCO3
MgO96.696.087.099.599.790.8
Mg(OH)296.097.182.710010095.0
MgCO387.082.775.399.798.658.5
unit [%].
Table 8. Mg residual ratio (RMg) for combined-addition As-removal tests at CAS0 = 10 mg/L.
Table 8. Mg residual ratio (RMg) for combined-addition As-removal tests at CAS0 = 10 mg/L.
ΣWAd/V = 0.4 g/LMgOMg(OH)2MgCO3CaOCa(OH)2CaCO3
MgO95.894.789.499.499.591.8
Mg(OH)294.797.385.210010095.2
MgCO389.485.278.397.495.364.6
unit [%].
Table 9. The combined-addition CMg minus the higher of the two single-addition CMgCMg) for As-removal tests at CAS0 = 1 mg/L.
Table 9. The combined-addition CMg minus the higher of the two single-addition CMgCMg) for As-removal tests at CAS0 = 1 mg/L.
ΣWAd/V = 0.4 g/LMgOMg(OH)2MgCO3CaOCa(OH)2CaCO3
MgO−3.0−2.61.0−10.6−10.80.6
Mg(OH)2−2.60.50.7−4.2−4.20.0
MgCO31.00.72.5−22.3−21.8−0.2
unit [mg/L].
Table 10. The combined-addition CMg minus the higher of the two single-addition CMgCMg) for As-removal tests at CAS0 = 10 mg/L.
Table 10. The combined-addition CMg minus the higher of the two single-addition CMgCMg) for As-removal tests at CAS0 = 10 mg/L.
ΣWAd/V = 0.4 g/LMgOMg(OH)2MgCO3CaOCa(OH)2CaCO3
MgO−0.20.4−2.3−9.8−9.8−0.4
Mg(OH)20.40.1−1.4−4.4−4.4−0.3
MgCO3−2.3−1.41.0−19.6−18.5−2.1
unit [mg/L].
Table 11. Ca residual ratio (RCa) for single-addition As-removal tests.
Table 11. Ca residual ratio (RCa) for single-addition As-removal tests.
WAd/V
[g/L]
CAS0
[mg/L]
MgOMg(OH)2MgCO3CaOCa(OH)2CaCO3
0.21---15.67.194.6
0.41---25.84.296.8
0.210---18.99.293.6
0.410---32.49.296.6
unit [%].
Table 12. Ca residual ratio (RCa) for combined-addition As-removal tests at CAS0 = 1 mg/L.
Table 12. Ca residual ratio (RCa) for combined-addition As-removal tests at CAS0 = 1 mg/L.
ΣWAd/V = 0.4 g/LMgOMg(OH)2MgCO3CaOCa(OH)2CaCO3
CaO29.029.153.925.816.536.9
Ca(OH)29.710.272.516.54.247.2
CaCO396.697.098.636.947.296.8
unit [%].
Table 13. Ca residual ratio (RCa) for combined-addition As-removal tests at CAS0 = 10 mg/L.
Table 13. Ca residual ratio (RCa) for combined-addition As-removal tests at CAS0 = 10 mg/L.
ΣWAd/V = 0.4 g/LMgOMg(OH)2MgCO3CaOCa(OH)2CaCO3
CaO31.335.642.332.425.444.4
Ca(OH)211.513.955.325.49.246.7
CaCO396.496.998.744.446.796.6
unit [%].
Table 14. The combined-addition CCa minus the higher of the two single-addition CCaCCa) for As-removal tests at CAS0 = 1 mg/L.
Table 14. The combined-addition CCa minus the higher of the two single-addition CCaCCa) for As-removal tests at CAS0 = 1 mg/L.
ΣWAd/V = 0.4 g/LMgOMg(OH)2MgCO3CaOCa(OH)2CaCO3
CaO−24.1−24.2−62.984.388.616.8
Ca(OH)24.3−1.1−71.888.6103−1.6
CaCO32.92.61.116.8−1.60.4
unit [mg/L].
Table 15. The combined-addition CCa minus the higher of the two single-addition CCaCCa) for As-removal tests at CAS0 = 10 mg/L.
Table 15. The combined-addition CCa minus the higher of the two single-addition CCaCCa) for As-removal tests at CAS0 = 10 mg/L.
ΣWAd/V = 0.4 g/LMgOMg(OH)2MgCO3CaOCa(OH)2CaCO3
CaO−18.0−21.5−33.476.774.710.6
Ca(OH)2−2.9−4.7−50.074.71022.9
CaCO32.92.41.110.62.90.2
unit [mg/L].
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Sugita, H.; Oguma, T.; Hara, J.; Zhang, M.; Kawabe, Y. Removal of Arsenate from Contaminated Water via Combined Addition of Magnesium-Based and Calcium-Based Adsorbents. Sustainability 2023, 15, 4689. https://doi.org/10.3390/su15054689

AMA Style

Sugita H, Oguma T, Hara J, Zhang M, Kawabe Y. Removal of Arsenate from Contaminated Water via Combined Addition of Magnesium-Based and Calcium-Based Adsorbents. Sustainability. 2023; 15(5):4689. https://doi.org/10.3390/su15054689

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Sugita, Hajime, Terumi Oguma, Junko Hara, Ming Zhang, and Yoshishige Kawabe. 2023. "Removal of Arsenate from Contaminated Water via Combined Addition of Magnesium-Based and Calcium-Based Adsorbents" Sustainability 15, no. 5: 4689. https://doi.org/10.3390/su15054689

APA Style

Sugita, H., Oguma, T., Hara, J., Zhang, M., & Kawabe, Y. (2023). Removal of Arsenate from Contaminated Water via Combined Addition of Magnesium-Based and Calcium-Based Adsorbents. Sustainability, 15(5), 4689. https://doi.org/10.3390/su15054689

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